Chapter 304 This flying device can be directly connected to the battery
The content published by the magazine "Nature" has become the focus of international scientific research.
There are only about twenty anti-gravity experimental teams in the world. Eighteen anti-gravity experimental teams work together to study the edge effect of superimposed force fields. This is a quite large-scale scientific research cooperation.
It can be said that all capable teams are involved.
This is enough to explain the problem.
For example, many scholars are concerned about the question, does the strong annihilation force really exist?
Although there is no clear evidence that the edge effect of the superimposed force field is directly related to the strong annihilation force, the least antigravity experimental team believes that the two are directly related and work together to conduct collaborative research.
Wang Hao's report on the principle of edge effects of superposed force fields was recognized by most scholars present, and they all believed that strong annihilation forces existed.
that's enough.
Many influential scholars have expressed their opinions on related topics, expressing their belief in the existence of strong annihilation forces, and are full of expectations for collaborative research on anti-gravity teams.
As a result, antigravity-related research has once again become an international focus.
Many people are talking about theories related to the strong annihilation force. The research on "particle behavior weakening" completed by Helen and Chen Mengmeng, and the expression of the strong annihilation force in the research, have naturally become the focus of the physics community.
At the same time, Wang Hao's analysis of the principle of internal changes in atoms in response to the edge effect of superimposed force fields at the conference was also published in the journal Nature Physics.
Those scholars who did not participate in the conference gained a deeper understanding of the edge effect of the superposed force field after reading the paper, and became more convinced that it is directly related to the strong annihilation force.
The famous Scottish physicist Brunson Jewell of the Newton Institute said in an interview that is very representative, "The annihilation force can be understood as the squeeze of space."
"Anti-gravity research, that is, reducing the intensity of space compression."
"The strong annihilation force naturally enhances the intensity of space compression, which is completely opposite to the anti-gravity effect. This is the interesting part."
"Using antigravity experiments, we can study the opposite edge effect of strong annihilation force, which reflects the wonder of physics."
"In physics, there will always be diametrically opposite but closely related phenomena, such as matter, antimatter, and supersymmetry issues in quantum physics."
"Any physics or substance will have its opposite side..."
"The strong annihilation force seems to reversely enhance the squeeze of space, which is equivalent to a brand-new physics. Based on the study of antigravity, we can deduce some special properties. For example, in the strong annihilation force field, particles
The performance will be more active, which is directly reflected in the increase in the speed of light."
"Of course, the weakening of particle properties is also a manifestation, but it has not been clearly proven."
Brunson-Jevil said a lot, and also showed his understanding of annihilation theory and anti-gravity research.
Many other physicists are also looking forward to research on strong annihilation forces.
Of course, not everyone is expecting it, and some people are greatly affected by the emergence of strong annihilation power.
For example, Soloane, editor-in-chief of the journal Science-Physics.
Solon was fired from Science magazine.
The day after the new issue of Nature magazine was published, Chalbert, the trustworthy person in charge of Science magazine, directly called Solone and said in a calm tone, "Mr. Solone, you can change
Already working."
Then, Solon could only pack up his things and leave.
Solon was in a very uneasy mood. Of course he knew why he was dismissed. It was because of his decision to publish two completely opposite papers together.
After the two papers were published, there was considerable controversy in public opinion.
Of course, Science magazine cannot be blamed for errors in the paper. Parsons' paper was reviewed normally, the physics editorial board could not find any errors, and the peer review was passed.
However, there are two major consequences.
A major consequence was that Wang Hao's research was considered correct, and the existence of the strong annihilation force was quickly confirmed, while Parsons was considered a 'liar'.
Naturally, many scholars began to criticize Science magazine, believing that they should not publish two completely different papers together.
Some scholars bluntly said, "Why can a paper that is completely opposite to Wang Hao's conclusion be published?"
This sentence makes no sense. It is impossible to say that research contrary to the research conclusion of a certain heavyweight scholar cannot be published.
But if you think about it carefully, it really makes sense!
Now it is not proven that Wang Hao's research is correct. Naturally, research that is contrary to his conclusion must be wrong.
Another point is that everyone pays attention to "Nature" magazine, because "Nature" magazine publishes highly influential content.
Why not Science magazine?
It was not because Solon decided to allow Parsons' paper to be published, which caused international public opinion issues, that Wang Hao himself decided not to publish the paper in Science.
So Solon was fired and he had no choice but to accept it.
As for Parsons…
A loser has long been forgotten.
…
After the meeting, Wang Hao returned to Xihai University and began to explain the work of the Antigravity Behavior Research Center.
Their first task that year was to conduct experiments according to the meeting assignments.
Wang Hao also hopes to conduct verification related to the impact of high magnetic fields on superimposed force fields, but similar research is not directly possible, and new experiments need to be designed based on the analysis of conclusions from experiments related to superimposed force fields.
In addition, if you want to create large-scale high magnetic fields, you need to introduce new equipment and upgrade the overall experimental equipment.
These all take time.
So after Wang Hao arranged his work, he devoted himself to the research and design of SMES batteries.
The design and research of SMES batteries has entered a critical period, at least according to Wang Hao.
A lot of design work preparations have been completed. The first technology that needs to be tackled is the new energy storage coil.
The new energy storage coil is the core of the SMES battery.
The energy storage coil is an energy storage and release device, and is naturally the most critical component of the battery. There are two most important points in related design, one is material selection, and the other is the proposed shape and winding method of the material.
The latter is relatively complicated, and the former is not easy to determine.
A few years ago, material selection was not a problem at all because they had no choice at all.
Things are different now. Superconducting Materials Industrial Company has produced several superconducting materials with a critical temperature exceeding 120K, which can be directly used in industry.
The critical temperature is different, and the properties of the material are also different.
Some materials can carry high current intensity, but the fluctuations affected by the environment are also large, and the critical temperature is relatively low.
Some materials meet the latter two requirements and can carry relatively low current intensity.
However, the choices of materials are still limited. Wang Hao went to the Superconducting Materials Industrial Company and spent only an hour to identify a new material, with the industrial code name 'CW013'.
The critical temperature of ‘CW013’ is 147K, and the current intensity it can carry is not low, and it also meets the design requirements for superconducting battery manufacturing.
The basis of this demand mainly refers to high-power ‘conversion output’.
After that, the experimental team began to demonstrate the design of the energy storage coil.
If you just improve the energy storage efficiency of the coil, there are of course many methods, but the most critical thing is to balance the energy storage efficiency and safety and stability issues.
The environment in which the energy storage coil is located is very special. High magnetic fields, continuous high internal current and temperature will all have an impact.
Whether it is instantaneous overcurrent, thermal disturbance, etc., it will cause a series of chain reactions, which is the quench problem of the energy storage coil.
In the original Pan Dong's team, Liang Jingye was responsible for solving quench-related problems, while Wang Hao's team had a perfect underlying design and did not encounter quench problems.
Now when designing a new energy storage coil, we must consider detection and safety balance issues.
Regarding the design of energy storage coils, Wang Hao's approach is to continuously hold demonstration meetings and ask the relevant responsible groups to come up with solutions for each problem.
That's certainly not a direct solution, just some ideas on the problem.
This is not enough.
It is impossible for a technical team to come up with a perfect solution to a problem.
Therefore, Wang Hao had to discuss each issue with many people. Some issues were discussed for a long time, and other technical team members were also asked to express their opinions.
This argument went on for a long time.
Wang Hao determined the design plan for each problem.
Many people in the experimental team participated in the demonstration work of the energy storage coil design, including of course Liang Jingye, who was Wang Hao's assistant and participated in the entire demonstration work, and also put forward many ideas during the process.
After working for a period of time, Liang Jingye discovered something strange.
The design of energy storage coils is very complicated, and the design of each part involves many factors. To solve some problems, it is almost impossible to come up with a perfect solution.
However, Wang Hao can always determine a design method. Even if this design method has problems of one kind or another, he will still decide on it and then move on to discuss other issues.
At first, Liang Jingye felt that Wang Hao's determination of the design plan was a bit hasty for certain problems, and he also put forward his own suggestions.
Then she was reminded by Liu Mingkun, "Xiao Liang, I know you must have your own ideas, and you are also very knowledgeable in energy storage coil technology."
Liang Jingye nodded seriously and listened.
Liu Mingkun continued, "But as long as Academician Wang has confirmed the design plan, you should not question it any more."
"Why?" Liang Jingye didn't understand.
Liu Mingkun said with a chuckle, "Actually, we were all the same at first. Later, you will find that Academician Wang is right."
He reminded you and said no more.
Liang Jingye was a little confused, but he discovered another problem. The people who raised questions about the design plan determined by Wang Hao were almost all people from Pan Dong's team and came to the research team with her.
The original old members of the experimental team would not question Wang Hao at all.
Liang Jingye had no choice but to suppress her inner thoughts and reminded others not to question the confirmed design plan.
soon.
Liang Jingye and others all understood Liu Mingkun's words.
Although the design plan determined by Wang Hao for a problem seems to have problems of one kind or another, when several certain technical solutions are combined together, many problems are directly solved.
Several design solutions for different technical problems can be said to be perfectly combined.
Many people in the experimental group were amazed.
They were all surprised by the final design plan, especially when they thought that every small detail of the design was finalized by Wang Hao.
Here comes the problem.
How was such a complex design plan determined item by item?
Even if they were discussing and doing research together, they couldn't imagine how Wang Hao did it.
In the end, they could only conclude, "Academician Wang is a genius!"
"We are far incomparable. Even if we do research together, we still can't figure it out at all."
"Maybe it's the difference in IQ. Although we live in the same space, our IQs are in different dimensions..."
…
The design of new superconducting energy storage coils is indeed a very complicated task.
It took the experimental team a month to finalize the design plan, and then notify the relevant cooperative factories for production. After having the experimental products, they started testing.
At the same time, background software systems such as detection, protection, and data monitoring are also being studied together.
Wang Hao divided the overall design into two parts, one is the core energy storage coil, and the other is the soft system that combines quench protection, automatic cooling control, power regulation, etc.
The latter is of course very important.
After completing the design of the new superconducting energy storage coil, the research on the soft system can begin.
The research on soft systems is more complicated than that of energy storage coils, and needs to be combined with the testing of energy storage coils for improvement.
This part of the work takes the longest.
The other part, the refrigeration system, is relatively easy. Because of the use of new high-temperature superconducting materials, the critical temperature has reached 147k. Temperature adjustment is relatively easy. You only need to ensure that the internal temperature of the energy storage coil is stable.
In the next step, the work of the experimental group will be transferred to the research of soft systems.
…
Two months later.
The experimental team has completed the testing of the energy storage coil, and a large part of the design work of the soft system has also been completed.
The next step is to prepare the experimental product.
This is not easy.
Although the test of the energy storage coil has been completed and the related soft systems are relatively complete, it is not easy to combine the coil, detection equipment, internal pipelines, etc. to create a corresponding SMES battery.
In terms of basic design, certain corrections and improvements still need to be made.
Wang Hao is also thinking about this issue.
The usage scenario of SMES batteries is not like that of civilian cars or drones, where the finished batteries can be manufactured and used.
SMES batteries are primarily designed to supply "anti-gravity aircraft", and subsequent demonstrations may be used in other large-scale equipment, even large-scale military equipment.
So how to assemble the SMES battery?
Wang Hao was a little unsure, so he simply put aside the battery research problem and went directly to the experimental base of the Aviation Industry Group team.
On this day, he received an invitation from the aviation group team to participate in the first take-off test of the ‘anti-gravity equipment’.
In fact, the anti-gravity flight device was not directly manufactured, but the "anti-gravity equipment" equipment was tested and launched into the air.
The so-called lift-off is just getting off the ground.
The Aviation Group team installed four small thrusters under the anti-gravity equipment, which was also connected to power lines.
Because the lateral anti-gravity technology reduces the weight of the equipment itself, the final weight of the equipment is less than two tons.
Then you can use small thrusters to lift off the anti-gravity equipment in place.
This is part of the experimental design of the anti-gravity flight device.
Although it is simply disconnected from the ground, and even the power comes from the connected lines, it is still very representative.
soon.
Wang Hao arrived at the aviation group team's experimental center and saw the so-called 'Line Energy' anti-gravity flight device.
In fact, it is similar to the experimental device used in antigravity research, except that everything including the cooling system has been separated and mounted on the antigravity device.
The only other connections to the ground are power lines.
After Wang Hao saw the device, he immediately thought of the SMES battery. His first reaction was, "You can try to install a superconducting coil, and then modify the interior. The electronic system is combined with the SMES battery soft system..."